Pulsed UV light source

ABSTRACT

There is described an ultraviolet light source comprising an ultraviolet bulb, a pulsed microwave energy source for exciting said ultraviolet bulb and an enclosure for enclosing the ultraviolet lamp, the enclosure comprising an optically transparent waveguide. The optically transparent waveguide wholly surrounds the bulb. The ultraviolet light source is particularly suitable for use in the sterilisation of substances; the promotion of photochemical reactions; and the promotion of molecular dissociation in liquids.

TECHNICAL FIELD

The present invention is in the field of pulsed ultraviolet (UV) light sources.

BACKGROUND TO THE INVENTION

It is known to use ultraviolet (UV) radiation in sterilisation systems for use in the purification of water and the sanitisation of a variety of items. The UV radiation and any ozone produced by the UV radiation with oxygen in the air acts to kill bacteria and germs. It is also known to use ultraviolet (UV) radiation for a variety of other uses including those involving the promotion of photochemical reactions and of molecular dissociation.

Conventional systems employ microwave energy to excite the source of UV radiation. One problem such systems is that it is difficult to efficiently provide sufficient excitation energy to the UV source and difficult to effectively transfer that energy to the substance or entity to be treated. It is therefore difficult to arrange systems for high energy, high throughput industrial purposes.

There is now described an ultraviolet light source which enables efficient, high throughput UV treatment to be conducted. The ultraviolet light source comprises an UV lamp which is excited by a microwave energy source. The lamp is enclosed by a waveguide comprising UV transparent material.

PCT Patent Applications Nos. WO 00/32244 and WO 01/09924 (in the name of the Applicant) describe non-pulsed ultraviolet light sources. The pulsed ultraviolet light sources of the present invention have been found to provide for enhanced efficacy (e.g. enhanced sterilising capability) and reduced power consumption when compared to the earlier described, non-pulsed ultraviolet light sources.

SUMMARY OF THE INVENTION

According to one aspect of the present invention there is provided an ultraviolet light source comprising an ultraviolet bulb; a pulsed microwave energy source for exciting said ultraviolet bulb; and an optically transparent waveguide for guiding pulsed microwave energy originating from said pulsed microwave energy source to the ultraviolet bulb. The waveguide wholly surrounds the ultraviolet bulb.

Typically, the waveguide forms an enclosure for the ultraviolet bulb.

The microwave energy source provides pulsed microwave energy to excite the ultraviolet bulb. Pulsed microwave energy sources are known in the art. In general, the ultraviolet light source herein requires pulsing at relatively high power levels at a relatively short pulse width.

Suitably, the microwave energy source can be pulsed with pulse widths ranging from 100 milliseconds to 0.5 microseconds, preferably from 10 milliseconds to 5 microseconds.

Suitably, the microwave energy source has a pulse period of from 100 milliseconds to 0.5 microseconds, preferably from 5 milliseconds to 50 microseconds.

Suitably, the microwave energy source can be pulsed at a frequency of from 2 MegaHertz to 10 Hertz.

Optimisation of both pulse width and pulse period is preferred.

Suitably, the peak operating energy of the bulb is from 100 watts to 100,000 watts, preferably from 500 watts to 30,000 watts.

In aspects herein, the lamp may be excited by both a continuous (i.e. non-pulsed) microwave energy source and a pulsed microwave energy source. In aspects, the ultraviolet light source additionally comprises a continuous microwave energy source, which may be separate from or integral with the pulsed microwave energy source.

Suitably, the energy consumption of pulsed excitation is significantly lower than that of continuous excitation. Typically, the pulsed energy for excitation is directly dependent on the pulse duty cycle (pulse width/pulse period).

Suitably, the peak energy value of pulsed excitation is significantly higher than that of the peak energy value of continuous excitation. Typical peak energy ratios are from 1:10 to 1:100 for continuous: pulsed energy levels. In one example, the lamp is excited at steady state by a continuous 100 watt energy source and pulsed at up to 3,000 watts by a pulsed excitation source.

In aspects, the ultraviolet light source may be arranged for the emission of either monochromatic or polychromatic ultraviolet radiation.

The dominant wavelength of the ultraviolet light source may be selected according to the particular application for which the light source is to be used.

In one aspect, the dominant wavelength of the ultraviolet light source is from 240 nm to 310 nm, particularly 254 nm. Such wavelengths have been found to be particularly useful for sterilisation, purification or sanitisation applications.

In another aspect, the dominant wavelength of the ultraviolet light source is from 140 to 260 nm, preferably from 150 to 220 nm, most preferably from 160 to 200 nm, particularly 182 nm or 185 nm. Such wavelengths have been found to be particularly useful for use in promoting molecular dissociation reactions.

In a further aspect, the dominant wavelength of the ultraviolet light source is from 310 to 400 nm, preferably from 320 to 380 nm, most preferably from 330 to 370 nm, particularly 346 nm. Such wavelengths have been found to be particularly useful for use in promoting certain photochemical reactions.

The ultraviolet light produced by the ultraviolet light source herein may additionally be channelled as a light source of high intensity. Suitable uses would include lighting within buildings and lighting for vehicles such as cars, lorries and buses.

By optically transparent waveguide it is meant a waveguide that is substantially transparent to the ultraviolet radiation employed herein, typically having a transparency of greater than 50%, preferably greater than 90% to UV radiation.

The waveguide controls the flow of ultraviolet radiation therefrom. The control function typically includes the prevention of the release of harmful or unnecessary ultraviolet radiation frequencies.

In aspects, the waveguide is provided with a sleeve (e.g. a quartz sleeve) and the material of that sleeve is selected to preferentially allow different wavelengths of UV radiation to escape. The exact nature of the waveguide and its control function can be tailored to fit the purpose of use.

Suitably, the ultraviolet bulb has no electrode. That is to say it is an electrode-less bulb such as one comprising a partially evacuated tube comprising an element or mixtures of elements in vapour form. Mercury is a preferred element for this purpose, but alternatives include mixtures of inert gases with mercury compounds, sodium and sulphur. Halides, such as mercury halide are also suitable herein. Amalgams are also suitable herein including indium/mercury amalgam.

Inevitably, such electrode-less bulbs emit a spectrum of wavelengths, dependent on the chemical nature of the core element or elements. Embodiments employing multiple lamps of different spectrum characteristics are envisaged herein.

In one aspect, the waveguide controls the flow of microwave energy therefrom. Control of the microwave energy which passes through the waveguide is useful in embodiments of the invention which make use of both UV and microwave radiation.

In another aspect, the waveguide blocks at least the majority of the flow of microwave energy therefrom.

Suitably, the waveguide comprises a sleeve therefor, and said sleeve is comprised of quartz or a UV-transparent plastic material. In general, a sleeved waveguide will be cylindrical in form.

Different configurations of waveguide and sleeve can be envisaged. In one aspect the waveguide is rectangular in form and has a quartz sleeve provided therearound. In another aspect, the waveguide is cylindrical in form (e.g. comprised of a metallic screen or mesh). Rectangular quartz-sleeved waveguides are in general more expensive than cylindrical mesh waveguides.

Suitably, the waveguide or any sleeve therefor is coated with a coating which assists in controlling the flow of ultraviolet and/or microwave energy therefrom. The coating may be applied to either or both of the inner or outer surfaces of the waveguide. Partial coatings are also envisaged.

Suitably, a system for cleaning the waveguide or any sleeve therefor (e.g. the quartz tube) is incorporated herein. Suitable cleaning systems include those based upon fluid flow, such as flow of water, air or gas. Cleaning agents such as detergents may be employed as necessary.

Suitably, the waveguide or any sleeve therefor comprises a conducting material. The conducting material may be integral, or applied as an internal or external coating or liner. The liner may directly contact the inner surface of the waveguide or be spaced therefrom.

In aspects, any sleeve for the waveguide and/or the ultraviolet bulb is coated with a coating that assists in modifying the wavelength of emitted light.

In other aspects, the waveguide is constructed to ensure control of the escape of microwave energy. For example, the waveguide can be adapted to include different hole spacings, wire thicknesses and overall configurations.

Suitably, the waveguide comprises a conducting mesh. Preferably, the conducting mesh comprises a high frequency conducting material selected from the group consisting of copper, aluminium and stainless steel.

The ultraviolet bulb has any suitable shape and size, including elongate forms such as a cigar-shape. The bulb size can be tailored. Typical bulb diameters are from 5 to 200 mm, for example 38 mm.

Embodiments are envisaged in which plural bulbs are employed. The bulb may be similar in type e.g. of similar size and operating temperature or combinations of different bulb types may be employed. The number of bulbs employed is tailored to the purpose of use. Typically from 2 to 25 bulbs are employed, such as from 3 to 18 bulbs. Various forms of arrangement of the plural bulbs are envisaged including random or informal arrangements, side-by-side arrangements, sequential arrangements, array arrangements and clusters. The bulbs may be arranged in serial, parallel or mixed serial and parallel electrical circuit arrangements.

The optically transparent waveguide has any suitable shape, such as cylindrical or rectangular forms. The length and size of the waveguide is tailored to fit the particular purpose of use and to provide an enclosure for the necessary bulb(s).

Suitably, the ultraviolet bulb has an operating temperature which maximises the chosen bulb characteristics. Typical operating temperatures are from 10° C. to 900° C., for example 40° C. to 200° C. and the operating temperature will be selected and optimised according to the purpose of use.

Suitably, the pulsed microwave energy source comprises a magnetron or other suitable microwave-producing device with suitable pulsing circuitry.

Suitably, the ultraviolet light source additionally comprises a system for cleaning the waveguide or any sleeve thereof (e.g. a quartz sleeve).

Suitably, the ultraviolet light source additionally comprises a pathguide to guide the pulsed microwave energy from the pulsed microwave energy source to the ultraviolet bulb.

In one aspect the pathguide defines an essentially linear path for the microwave energy.

In another aspect, the pathguide defines a non-linear path such as a path defining an angle, such as a right angle.

Suitably, the pathguide comprises a coaxial cable.

Suitably, the ultraviolet light source additionally comprises a housing for said waveguide. Preferably, the housing has an inlet and an outlet and the housing is shaped to guide fluid flow from the inlet past the waveguide (e.g. along a protective sleeve for the waveguide) to the outlet. Preferably, the fluid comprises air or a liquid such as water. Suitably, the ultraviolet light source additionally comprises a pump for pumping fluid from the inlet, past the waveguide to the outlet. Alternatively, gravity may be utilised to encourage fluid flow.

The choice of materials for use in the housing and any fluid flow piping arrangements can be important. Typically, the materials will be selected which are resistant to corrosion and which do not leach contaminants to the system. Seal materials are also carefully selected with typical seal materials including Chemraz (trade name), Teflon (trade name), encapsulated Viton (trade name) and GORE-TEX (trade name).

According to another aspect of the present invention there is provided a lamp comprising an ultraviolet bulb, said bulb being excitable by pulsed microwave energy; and an optically transparent waveguide for guiding pulsed microwave energy originating from a pulsed microwave energy source to the ultraviolet bulb, wherein said waveguide wholly surrounds the ultraviolet bulb.

Preferably, the ultraviolet bulb has no electrode.

According to a further aspect of the present invention there is provided a method of sterilising a substance comprising applying pulsed microwave energy to an ultraviolet lamp to produce ultraviolet radiation of dominant wavelength of from 240 nm to 310 nm; and exposing the substance to said ultraviolet radiation, wherein an optically transparent waveguide guides said pulsed microwave energy to said ultraviolet lamp and said waveguide wholly surrounds the ultraviolet lamp.

The sterilising method aspect herein is suitable for use in sterilising a variety of substances including water for human consumption; waste water and sewage; metallic and non-metallic objects including medical instruments; air in buildings such as hospitals, offices and homes; and in prolonging the shelf-life of foodstuffs (e.g. fruit and vegetables) by killing bacteria on the surface thereof.

The sterilising method aspect herein is suitable in one aspect for use in air-conditioning systems for use in vehicles such as cars, lorries and buses. The system will be sized and shaped to fit within the air-conditioning system of the vehicle and will typically therefore have a size less than the size it would possess when used in large scale air and water treatment applications.

According to a further aspect of the present invention there is provided a method of promoting the dissociation of a molecular entity comprising applying pulsed microwave energy to an ultraviolet lamp to produce ultraviolet radiation of dominant wavelength of from 140 to 260 nm; and exposing the molecular entity to said ultraviolet radiation, wherein an optically transparent waveguide guides said pulsed microwave energy to said ultraviolet lamp and said waveguide wholly surrounds the ultraviolet lamp.

In one aspect, the molecular entity is borne in a fluid such as air or a liquid and the fluid flows past the enclosure. A specific example of this is in the clean up of ballast seawater from the holds of ships wherein contaminants in the ballast water are dissociated by application of ultraviolet radiation.

A further specific example of molecular dissociation applications based on fluid flow is in the dissociation of organic material, such as Total Oxidisable Carbon (TOC) in rinse water for use in the electronics, semiconductors pharmaceuticals, beverage, cosmetics and power industries. The process involves the production of OH• radicals which oxidise any hydrocarbon molecules in the rinse water. Optionally, other oxidants may be employed such as ozone and hydrogen peroxide. Typically, polishing deionisation beds, featuring nuclear-grade resin materials are placed downstream of the TOC reduction units to remove any ionised species and restore the resitivity of the water.

In another aspect, the molecular entity is borne on a surface and the ultraviolet radiation is applied to the surface to eliminate any bacterial contaminants by disinfection. The molecular entity may, for example be a contaminant on the surface which is rendered harmless by its molecular dissociation.

In one example, the surface is of a food product such as a meat, dairy, fish, fruit or vegetable product and the ultraviolet radiation is applied to the surface to dissociate any contaminants such as chemical residues including pesticides.

In another example, the surface is an industrially-produced product such as a packaging product for example, a medical packaging product, a foil bag, cup or lid, or a glass or plastic bottle, and the ultraviolet radiation is applied to the surface to dissociate any contaminants arising from the industrial process.

In a further example, the surface is the surface of any equipment used in the manufacture of food products or industrially produced products such as the surface of any reactors or conveyors.

According to a still further aspect of the present invention there is provided a method of promoting a photochemical reaction in a substance comprising applying pulsed microwave energy to an ultraviolet lamp to produce ultraviolet radiation of dominant wavelength of from 310 to 400 nm; and exposing the entity to said ultraviolet radiation, wherein an optically transparent waveguide guides said pulsed microwave energy to said ultraviolet lamp and said waveguide wholly surrounds the lamp.

In one aspect, the substance is borne in a fluid such as air or a liquid and the substance-bearing fluid flows past the enclosure.

In another aspect, the substance is borne on a surface and the ultraviolet radiation is applied to the surface.

Preferably, the substance is selected from the group consisting of surface treatment materials including paints, toners, varnishes (e.g. polyurethane varnishes), stains and laminating materials.

Laminating is for example, used in the production of various electronic components, data storage devices including compact discs and packaging materials including blister packages.

In another method aspect herein, the exposure of a biological substance to wavelengths of less than 200 nm or from 300–400 nm has been found to help to prevent DNA recovery. This may for example, be of use in the elimination of biological contaminants and pests e.g. insects.

In the method aspects herein, the microwave energy suitably has a pulse width of from 100 milliseconds to 0.5 microseconds, preferably from 10 milliseconds to 5 microseconds. Suitably, the microwave energy has a pulse cycle of from 100 milliseconds to 0.5 microseconds, preferably from 5 milliseconds to 50 microseconds. Optimisation of both pulse width and pulse cycle is preferred.

Suitably, the peak operating energy of the bulb is from 100 watts to 100,000 watts, preferably from 500 watts to 30,000 watts.

According to a further aspect of the present invention there is provided an ultraviolet light source comprising a plurality of ultraviolet bulbs; a pulsed microwave energy source for exciting said plurality of ultraviolet bulbs; and an optically transparent waveguide for guiding pulsed microwave energy originating from said pulsed microwave energy source to the plurality of ultraviolet bulbs, wherein said waveguide wholly surrounds the plurality of ultraviolet bulbs.

According to a further aspect of the present invention there is provided a lamp comprising a plurality of ultraviolet bulbs, said plurality of bulbs being excitable by pulsed microwave energy; and an optically transparent waveguide for guiding pulsed microwave energy originating from a pulsed microwave energy source to the plurality of ultraviolet bulbs, wherein said waveguide wholly surrounds the plurality of ultraviolet bulbs.

BRIEF DESCRIPTION OF THE DRAWINGS

Preferred embodiments of the ultraviolet light source in accord with the present invention will now be described with reference to the accompanying drawings in which:

FIG. 1 is a schematic representation of a first ultraviolet light source herein;

FIGS. 2 a and 2 b are schematic representations of second and third ultraviolet light sources herein;

FIGS. 3 a and 3 b are schematic representations of fourth and fifth ultraviolet light sources herein;

FIG. 4 is a schematic representation of a sixth ultraviolet light source herein suitable for use in combined UV and microwave methods;

FIG. 5 is a schematic representation of a seventh ultraviolet light source herein;

FIG. 6 is a schematic representation of an eighth ultraviolet light source herein;

FIG. 7 is a schematic representation of a ninth ultraviolet light source herein;

FIG. 8 is a schematic representation of a tenth ultraviolet light source herein;

FIG. 9 is a cross-sectional view of an ultraviolet lamp herein comprising twelve UV bulbs; and

FIG. 10 is a schematic representation of a suitable pulsed microwave energy wave herein.

DETAILED DESCRIPTION OF THE INVENTION

The present invention is here described by means of examples, which constitute possible embodiments of the invention.

FIG. 1 shows an ultraviolet light source comprising an ultraviolet lamp 10 enclosed by cylindrical enclosure 20. The cylindrical walls of the enclosure 20 are comprised of quartz material which is transparent to UV radiation. A conducting copper mesh 30 is provided to act as a waveguide. First end of the cylindrical enclosure has blocking end flange 22 provided thereto. The second end is provided with coupling flange 24 which couples with right angled pathguide 40 which in turn connects with rectangular pathguide 50. Magnetron 60 acts as a pulsed microwave energy source to feed pulsed microwave energy into the rectangular waveguide 50, thence into the right angled pathguide 40 and finally to the ultraviolet lamp 10 which is excited thereby.

The enclosure 20 is within tubular housing 70. The housing 70 has a fluid inlet 72 and a fluid outlet 74 provided thereto. In use, fluid flows from the inlet 72 past the enclosure 20 and towards the outlet 74. As the fluid flows past the enclosure 20 it is irradiated with UV radiation produced by the ultraviolet lamp 10. The radiation itself passes through the UV transparent walls of the enclosure 20 a, 20 b to contact the fluid. In one aspect, the fluid is water and the dominant wavelength of emitted UV radiation is 254 nm.

FIGS. 2 a and 2 b show related ultraviolet light sources herein. Both comprise ultraviolet mercury discharge lamp 110 a, 110 b enclosed by cylindrical enclosure 120 a, 120 b. The cylindrical walls of the enclosure 120 a, 120 b form a sleeve comprised of quartz material which is transparent to UV radiation. A conducting copper mesh waveguide 130 a, 130 b is provided to the inner surface of the sleeve. The enclosure 120 a, 120 b has air or nitrogen circulating therein. First end of the cylindrical enclosure has blocking end flange 122 a, 122 b provided thereto. The second end is provided with coupling flange 124 a, 124 b which couples with water-tight chamber 150 a, 150 b which contains brass waveguide 140 a, 140 b and magnetron 160 a, 160 b. The magnetron 160 a, 160 b acts as a pulsed microwave energy source to feed pulsed microwave energy into the brass waveguide 140 a, 140 b and thence to the ultraviolet lamp 110 a, 110 b which is excited thereby.

The enclosure 120 a, 120 b is within tubular housing 170 a, 170 b. The housing 170 a, 170 b has a fluid inlet 172 a, 172 b and a fluid outlet 174 a, 174 b provided thereto. In use, fluid flows from the inlet 172 a, 172 b past the enclosure 120 a, 120 b and towards the outlet 174 a, 174 b. As the fluid flows past the enclosure 120 a, 120 b it is irradiated with UV radiation produced by the ultraviolet lamp 110 a, 110 b. The radiation itself passes through the UV transparent walls of the enclosure 120 a, 120 b to contact the fluid. In one aspect, the dominant wavelength is 254 nm.

FIGS. 3 a and 3 b show ultraviolet light sources similar in structure to the ultraviolet light sources of FIGS. 2 a and 2 b but for use in treatment of airborne substances. Both comprise ultraviolet mercury discharge lamp 210 a, 210 b enclosed by cylindrical enclosure 220 a, 220 b. The cylindrical walls of the enclosure 220 a, 220 b are comprised of quartz material which is transparent to UV radiation. A conducting copper mesh waveguide 230 a, 230 b is provided to the inner surface of the waveguide. The enclosure 220 a, 220 b has air or nitrogen circulating therein. First end of the cylindrical enclosure has blocking end flange 222 a, 222 b provided thereto. The second end is provided with coupling flange 224 a, 224 b which couples with airtight chamber 250 a, 250 b containing brass waveguide 240 a, 240 b and magnetron 260 a, 260 b. The magnetron 260 a, 260 b acts as a pulsed microwave energy source to feed pulsed microwaves into brass waveguide 240 a, 240 b and thence to the ultraviolet lamp 210 a, 210 b which is excited thereby.

The enclosure 220 a, 220 b is within tubular housing 270 a, 270 b. The housing 270 a, 270 b has an air inlet 272 a, 272 b and an air outlet 274 a, 274 b provided thereto. In use, air flows from the inlet 272 a, 272 b past the enclosure 220 a, 220 b and towards the outlet 274 a, 274 b. As the air flows past the enclosure 220 a, 220 b it is irradiated with UV radiation produced by the ultraviolet lamp 210 a, 210 b. The radiation itself passes through the UV transparent walls of the enclosure 220 a, 220 b to contact the air, thereby treating molecular entities carried in the air.

In variations, the systems of FIGS. 1; 2 a and 2 b; 3 a and 3 b may be provided with cooling systems to enable the cooling of the magnetron and/or lamp.

FIG. 4 shows a cabinet ultraviolet light source herein suitable for use in treating objects herein. Ultraviolet mercury discharge lamp 310 is enclosed by cylindrical enclosure 320. The cylindrical walls of the enclosure 320 are comprised of quartz material which is transparent to UV radiation but only partially transparent to microwave radiation. A conducting copper mesh waveguide 330 is provided to the inner surface of the enclosure 320. The enclosure 320 optionally has air or nitrogen circulating therein. First end of the cylindrical enclosure has blocking end flange 322 provided thereto. The second end is provided with coupling flange 324 which couples with linear pathguide 340 which in turn connects with magnetron 360. The magnetron 360 acts as a pulsed microwave energy source to feed pulsed microwaves into pathguide 340 and thence to the ultraviolet lamp 310 which is excited thereby.

The enclosure 320 is within housing 370 which has an entry door 380 provided thereto. In use, items to be treated are placed in the housing 370. The items are irradiated with pulsed UV radiation produced by the ultraviolet lamp 310 and by pulsed microwave radiation deriving from the magnetron 360. The radiation itself passes through the UV transparent and microwave partially transparent walls of the enclosure 320 to contact the items. Optionally, the housing 370 may be provided with UV transparent shelves for the items. An inner reflective lining, for example an aluminium foil lining, may also be provided to the housing 370.

FIG. 5 shows an ultraviolet light source comprising an ultraviolet bulb 410 enclosed by cylindrical enclosure 420. The cylindrical walls of the enclosure 420 are comprised of quartz material which is transparent to UV radiation. The quartz tube enclosure 420 is provided with a cleaning system comprising wiper 480 which is mounted for movement on track 482. The track 482 is arranged parallel to the enclosure 420 and the movement of the wiper 480 is powered by motor 484.

A conducting copper mesh waveguide 430 is provided to the inner surface of the enclosure 420. An end of the enclosure 420 couples with coupling flange 424 which couples with stainless steel cylindrical pathguide 440 which in turn connects with stainless steel rectangular pathguide 450. Magnetron 460 acts as a pulsed microwave energy source to feed pulsed microwaves into the rectangular pathguide 450, thence into the cylindrical pathguide 440 and finally to the ultraviolet lamp 410 which is excited thereby.

The enclosure 420 is within stainless steel housing 470. The housing 470 has a fluid inlet 472 and a fluid outlet 474 provided thereto. In use, fluid flows from the inlet 472 past the enclosure 420 and towards the outlet 474. As the fluid flows past the enclosure 420 it is irradiated with UV radiation produced by the ultraviolet bulb 410. The radiation itself passes through the UV transparent walls of the enclosure 420 to contact the fluid.

In variations, another form of wiper arrangement may be employed which comprises plural (e.g. two) helical blades (similar to cylindrical lawn mower blades) arranged along the length of the quartz enclosure sleeve 420. As fluid flows along the outside of the enclosure 420 these blades will rotate and if a suitable material is placed on the inner edge of each blade cleaning of the quartz sleeve 420 will be promoted.

FIG. 6 shows an ultraviolet light source comprising two ultraviolet bulbs 510, 511 fixed in a mutually parallel arrangement by lamp supports 514, 515. The bulbs 510, 511 are enclosed by cylindrical enclosure 520. An air coolant system is provided to the bulbs 510, 511 wherein cooling air is fed into the enclosure 520 through air inlet 526 and circulates past the bulbs before exiting at air outlet 528. The cylindrical walls of the enclosure 520 are comprised of quartz material which is transparent to UV radiation. The quartz tube enclosure 520 is provided with a cleaning system comprising wiper 580 which is mounted for movement on track 582. The track 582 is arranged parallel to the enclosure 520 and the movement of the wiper 580 is powered by motor 584.

A conducting copper mesh waveguide 530 is provided to the inner surface of the waveguide. An end of the enclosure 520 couples with coupling flange 524 which couples with stainless steel rectangular pathguide 550. Magnetron 560 acts as a pulsed microwave energy source to feed pulsed microwaves into the rectangular pathguide 550 and thence to the ultraviolet lamp 510 which is excited thereby.

The enclosure 520 is within stainless steel housing 570 having observation port 571. The housing 570 has a fluid inlet 572 and a fluid outlet 574 provided thereto. In use, fluid flows from the inlet 572 past the enclosure 520 and towards the outlet 574. As the fluid flows past the enclosure 520 it is irradiated with UV radiation produced by the ultraviolet bulbs 510, 511. The radiation itself passes through the UV transparent walls of the enclosure 520 to contact the fluid.

FIG. 7 shows an ultraviolet light source comprising two ultraviolet bulbs 610, 611 fixed in a mutually parallel arrangement by lamp supports 614, 615. The bulbs 610, 611 are enclosed by cylindrical enclosure 620. An air coolant system is provided to the bulbs 610, 611 wherein cooling air is fed into the enclosure 620 through air inlet 626 and flows past the bulbs 610, 611 before exiting at air outlets 628, 629. The cylindrical walls of the enclosure 620 are comprised of quartz material which is transparent to UV radiation. The quartz tube enclosure 620 is provided with a cleaning system comprising wiper 680 which is mounted for movement on track 682. The track 682 is arranged parallel to the enclosure 620 and the movement of the wiper 680 is powered by motor 684.

A conducting copper mesh waveguide 630 is provided to the inner surface of the waveguide. An end of the enclosure 620 couples with coupling flange 624 which couples with stainless steel rectangular pathguide 650. Magnetron 660 acts as a pulsed microwave energy source to feed pulsed microwaves into the rectangular pathguide 650 and thence to the ultraviolet bulbs 610, 611 which are excited thereby.

The enclosure 620 is within stainless steel housing 670 having observation port 671. The housing 670 has a fluid inlet 672 and a fluid outlet 674 provided thereto. In use, fluid flows from the inlet 672 past the enclosure 620 and towards the outlet 674. As the fluid flows past the enclosure 620 it is irradiated with pulsed UV radiation produced by the ultraviolet bulbs 610, 611. The radiation itself passes through the UV transparent walls of the enclosure 620 to contact the fluid.

FIG. 8 shows an ultraviolet light source based on a series arrangement of a pair of ultraviolet light sources of the type illustrated in FIG. 7. The ultraviolet source comprises two pairs of ultraviolet bulbs 710 a, 711 a and 710 b, 711 b fixed in a mutually parallel arrangement by lamp supports 714 a, 715 a and 714 b, 715 b. The bulbs 710 a, 711 a and 710 b, 710 b are each enclosed by cylindrical enclosures 720 a, 720 b. An air coolant system is provided each pair of bulbs 710 a, 711 a and 710 b, 711 b wherein cooling air is fed into the enclosures 720 a, 720 b through air inlets 726 a, 726 b and flows past the bulbs 710 a, 711 a and 710 b, 711 b before exiting at air outlets 728 a, 729 a and 728 b, 729 b. The cylindrical walls of the enclosures 720 a, 720 b are comprised of quartz material which is transparent to UV radiation. The quartz tube enclosures 720 a, 720 b are each provided with a cleaning system comprising wiper 780 a, 780 b which is mounted for movement on respective track 782 a, 782 b. The tracks 782 a, 782 b are arranged parallel to the enclosures 720 a, 720 b and the movement of the wipers 780 a, 780 b is powered by motors 784 a, 784 b.

A conducting copper mesh waveguide 730 a, 730 b is provided to the inner surface of the waveguide. An end of each enclosure 720 a, 720 b couples with coupling flange 724 a, 724 b which couples with stainless steel rectangular pathguide 750 a, 750 b. Magnetrons 760 a, 760 b act as pulsed microwave energy sources to feed pulsed microwaves into the respective rectangular pathguides 750 a, 750 b and thence to the ultraviolet bulbs 710 a, 711 a and 710 b, 711 b which are excited thereby.

The quartz enclosures 720 a, 720 b are within a stainless steel housing comprising two interconnected arms 770 a, 770 b each having an observation port 771 a, 771 b. The first arm of the housing 770 a has a fluid inlet 772 and the second arm of the housing 770 b has a fluid outlet 774 provided thereto. In use, fluid flows from the inlet 772 past the first enclosure 720 a, through passages 773 a, 773 b, then past the second enclosure 720 b and finally towards the outlet 774. As the fluid flows past the enclosures 720 a, 720 b it is irradiated with UV radiation produced by the ultraviolet bulbs 710 a, 711 a and 710 b, 711 b. The radiation itself passes through the UV transparent walls of the enclosures 720 a, 720 b to contact the fluid.

Whilst in each of FIGS. 1 to 8 the magnetron is arranged locally to the lamp it may be appreciated that in other embodiments the magnetron is distally located and communicates with the lamp via a coaxial cable feed arrangement. Such coaxial cable feed arrangements are known in the art for example, described in Japanese Patent Publication No. 61046290.

FIG. 9 shows in cross-sectional view an ultraviolet lamp herein. The lamp comprises two rows 810 a, 810 b of six bulbs forming a six by two lamp array arrangement. The array of bulbs 810 a, 810 b is surrounded by a copper mesh 830 having a rectangular cross-section. Both the array of bulbs 810 a, 810 b and the copper mesh 830 are enclosed by a quartz tube 820 having a circular cross-section.

It may be appreciated that lamps comprising plural bulbs in any suitable arrangement may be employed in variations of the ultraviolet light sources shown in FIGS. 1 to 8.

FIG. 10 shows a suitable pulsed microwave energy waveform herein, as would be produced by the magnetron of any of FIGS. 1 to 8 using known pulsing circuitry. The defining characteristics of the waveform are the pulse width (X) which is typically short; the pulse period (Y) which is typically much longer; and the peak operating energy (intensity) of the microwave (Z). It will be appreciated that continuous (i.e. non-pulsed) microwave energy may also be used herein in combination with the pulsed microwave energy to excite the bulb of the ultraviolet light source of the invention. 

1. A liquid treatment apparatus comprising: (i) an ultraviolet light source, comprising: an ultraviolet bulb; a pulsed microwave energy source for exciting said ultraviolet bulb; and an optically transparent waveguide for guiding pulsed microwave energy originating from said pulsed microwave energy source to the ultraviolet bulb, wherein said waveguide wholly surrounds the ultraviolet bulb, and wherein the waveguide is provided with a blocking end flange; and (ii) a housing, said housing having an inlet and an outlet, the housing shaped to guide liquid flow from the inlet, past the waveguide to the outlet; wherein the dominant wavelength of the ultraviolet light source is from 240 to 310 nm.
 2. A liquid treatment apparatus according to claim 1, wherein the pulsed microwave energy source emits microwave energy with a pulse width of from 100 milliseconds to 0.5 microseconds.
 3. A liquid treatment apparatus according to either of claims claim 1, wherein the pulsed microwave energy source emits microwave energy with a pulse period of from 100 milliseconds to 0.5 microseconds.
 4. A liquid treatment apparatus according to claim 1, wherein the peak operating energy of the bulb is from 100 watts to 100,000 watts.
 5. A treatment apparatus according to claim 1, additionally comprising a continuous microwave energy source.
 6. A liquid treatment apparatus according to claim 5, wherein the ratio of peak energy of excitation of said continuous microwave energy source to the pulsed microwave energy source is 1:10 to 1:100.
 7. A liquid treatment apparatus according to claim 1, arranged for the emission of either monochromatic or polychromatic ultraviolet radiation.
 8. A treatment apparatus according to claim 1, wherein the ultraviolet bulb has no electrode.
 9. A liquid treatment apparatus to claim 1, wherein the waveguide controls the flow of microwave energy therefrom.
 10. A liquid treatment apparatus according to claim 9, wherein the waveguide blocks a majority of the flow of microwave energy therefrom.
 11. A liquid treatment apparatus according to claim 1, wherein the waveguide comprises a sleeve therefor and said sleeve is comprised of quartz or a UV-transparent plastic material.
 12. A liquid treatment apparatus according to claim 1, wherein the waveguide comprises a conducting material.
 13. A liquid treatment apparatus according to claim 12, wherein the conducting material is a coating or liner to the waveguide.
 14. A liquid treatment apparatus according to claim 12, wherein the waveguide comprises a conducting mesh.
 15. A liquid treatment apparatus according to claim 14, wherein the conducting mesh comprises a material selected from the group consisting of copper, aluminium and stainless steel.
 16. A liquid treatment apparatus according to claim 1, wherein the ultraviolet bulb has an elongate form.
 17. A liquid treatment apparatus according to claim 1, comprising plural ultraviolet bulbs.
 18. A liquid treatment apparatus according to claim 17, comprising from 2 to 25, preferably from 3 to 18 bulbs.
 19. A liquid treatment apparatus according to claim 17, wherein said plural ultraviolet bulbs form an arrangement selected from the group consisting of a random arrangement, a side-by-side arrangement, a sequential arrangement, an array arrangement and a cluster arrangement.
 20. A liquid treatment apparatus according to claim 1, wherein the optically transparent waveguide has a cylindrical or rectangular form.
 21. A liquid treatment apparatus according to claim 1, wherein the pulsed microwave energy source comprises a magnetron.
 22. A liquid treatment apparatus according to claim 1, additionally comprising a system for cleaning the enclosure.
 23. A liquid treatment apparatus according to claim 1, additionally comprising a pathguide to guide the microwave energy from the microwave energy source to the ultraviolet bulb.
 24. A liquid treatment apparatus according to claim 23, wherein the pathguide defines an essentially linear path.
 25. A liquid treatment apparatus according to claim 23, wherein the pathguide defines a non-linear path.
 26. A liquid treatment apparatus according to claim 23, wherein the pathguide comprises a coaxial cable.
 27. A liquid treatment apparatus according to claim 1, additionally comprising a pump for pumping fluid from the inlet, past the enclosure to the outlet. 